CNC machining relies on three core elements to deliver efficient, resultados de alta calidad: velocidad de corte, tool feed, y profundidad de corte. These elements are like the “engine, transmission, and fuel” of a car—each works independently but must be balanced to avoid mistakes like tool damage, Mal acabado superficial, or wasted time. This guide breaks down each element of CNC machining, solves common parameter-setting problems, and helps you optimize them for your specific project.
1. Velocidad de corte: The “Speed Limit” for Tool and Material
Velocidad de corte is the speed at which the workpiece or tool moves relative to each other during machining (measured in m/min or ft/min). It directly impacts how fast you can machine a part—and how long your tool lasts.
1.1 Key Factors That Determine Cutting Speed
Cutting speed isn’t one-size-fits-all. It depends on three critical factors:
- Material de herramienta: Harder tools handle faster speeds. Herramientas de carburo (common in industrial CNC) can run 3–5x faster than high-speed steel (HSS) herramientas.
- Material de pie de trabajo: Materiales blandos (P.EJ., aluminio) allow faster speeds than hard materials (P.EJ., acero inoxidable).
- Machining Conditions: Wet machining (con refrigerante) lets you increase speed by 20–30% (coolant reduces heat and tool wear).
The table below shows recommended cutting speeds for common tool-workpiece pairs:
Material de herramienta | Material de pie de trabajo | Dry Machining Speed (m/mi) | Wet Machining Speed (m/mi) |
Carburo | Aluminio | 300–500 | 400–600 |
Carburo | Acero inoxidable | 80–120 | 100–150 |
HSS | Aluminio | 100–150 | 120–180 |
HSS | Acero inoxidable | 20–40 | 30–50 |
1.2 Common Problem Solved: “Why is my tool wearing out too fast?"
You’re likely using a cutting speed that’s too high for your tool-workpiece pair. Por ejemplo:
- If you run a carbide tool on stainless steel at 200 m/mi (seco), the tool will overheat and wear out in 30 minutos.
- Lower the speed to 100 m/mi (seco), and the tool lasts 4–6 hours—saving you money on tool replacements.
2. Tool Feed: Balancing Surface Quality and Efficiency
Tool feed is the distance the tool moves along the workpiece per revolution (measured in mm/rev or inches/rev). It controls two key outcomes: aspereza de la superficie (how smooth the part is) and machining time.
2.1 How to Choose Tool Feed
The right feed rate depends on whether you’re doing rough machining (removing material quickly) o finish machining (creating a smooth surface):
- Mecanizado áspero: Use a larger feed rate (0.2–0.5 mm/rev) to remove material fast. Por ejemplo, when cutting a 100mm aluminum block down to 80mm, a 0.4 mm/rev feed cuts the block in 5 minutos (VS. 10 minutes with a 0.2 mm/rev feed).
- Terminar mecanizado: Use a smaller feed rate (0.05–0.15 mm/rev) Para superficies lisas. A 0.1 mm/rev feed on a stainless steel part creates a surface roughness (Real academia de bellas artes) de 1.6 μm—smooth enough for visible parts like consumer electronics.
2.2 Consideraciones críticas
- Potencia de la máquina: A weak CNC machine (low horsepower) can’t handle large feed rates—too much feed will stall the spindle.
- Tool Rigidity: Largo, thin tools need smaller feeds (0.05–0,1 mm/revolución) Para evitar la vibración (which ruins surface quality). Corto, thick tools can handle larger feeds.
Ejemplo: A user is finish-machining a aluminum phone case. They start with a 0.2 mm/rev feed and get a rough surface (Real academia de bellas artes 6.3 μm). They lower the feed to 0.1 mm/vuelta, and the surface becomes smooth (Real academia de bellas artes 1.6 μm)—perfect for a consumer product.
3. Profundidad de corte: Minimizing Passes Without Breaking Tools
Profundidad de corte is the distance the tool penetrates into the workpiece per pass (measured in mm or inches). It’s all about efficiency—using a larger depth reduces the number of passes, but too much depth can damage the tool or workpiece.
3.1 Rules for Choosing Depth of Cut
Siga estas pautas para evitar errores:
- Prioritize Large Depths (Cuando sea posible): On rough machining, use the largest depth your tool and machine can handle. For a carbide tool cutting aluminum, a 5–10 mm depth per pass is safe—this cuts a 50mm thick block in 5–10 passes (VS. 25 passes with a 2 mm de profundidad).
- Limit Depth for Hard Materials: For stainless steel or titanium, keep depth under 2–3 mm per pass (hard materials put more stress on tools).
- Finish Machining Needs Small Depths: Use a 0.1–0.5 mm depth for finish passes—this removes small imperfections without altering the part’s dimensions.
3.2 Common Problem Solved: “Why is my workpiece deforming during machining?"
You’re using a depth of cut that’s too large for the workpiece’s rigidity. Por ejemplo:
- A thin aluminum sheet (2mm de grosor) can’t handle a 1.5 mm depth of cut—the sheet will bend under the tool’s force.
- Reduce the depth to 0.5 mm por pase, and the sheet stays flat—ensuring the final part meets your size requirements.
4. How to Balance the Three Elements: Una guía paso a paso
The biggest challenge isn’t setting each element individually—it’s balancing them to get fast, resultados de alta calidad. Follow this process:
- Start with Cutting Speed: Pick a speed based on your tool and workpiece (use the table in Section 1.1). Por ejemplo: Carbide tool + aluminum = 400 m/mi (húmedo).
- Choose Tool Feed: Match feed to machining type. Rough machining = 0.3 mm/vuelta; finish machining = 0.1 mm/vuelta.
- Set Depth of Cut: Use the largest safe depth. Para mecanizado áspero: 8 mm por pase (aluminio); for finish machining: 0.3 mm por pase.
- Prueba y ajuste: Run a small test part. If the tool wears fast, lower the speed. If the surface is rough, reduce the feed. If the part deforms, decrease the depth.
Ejemplo: A manufacturer needs to machine 100 soportes de aluminio. They balance the elements as follows:
- Velocidad de corte: 400 m/mi (carburo + wet machining).
- Tool Feed: 0.3 mm/vuelta (bruto) → 0.1 mm/vuelta (finalizar).
- Profundidad de corte: 8 milímetros (bruto) → 0.3 milímetros (finalizar).
Resultado: Each bracket takes 12 minutes to make (VS. 20 minutes with unbalanced settings), and the tools last 8 horas.
5. Real-World Scenarios: Applying the Elements to Common Projects
See how the three elements work together for different CNC jobs:
Proyecto | Tool/Workpiece | Velocidad de corte (m/mi) | Tool Feed (mm/vuelta) | Profundidad de corte (milímetros) | Machining Time per Part |
Aluminum Phone Case | Carbide/Aluminum | 400 (húmedo) | 0.3 (bruto) → 0.1 (finalizar) | 5 (bruto) → 0.3 (finalizar) | 12 minutos |
Stainless Steel Gear | Carbide/Stainless Steel | 120 (húmedo) | 0.2 (bruto) → 0.08 (finalizar) | 2 (bruto) → 0.2 (finalizar) | 45 minutos |
HSS Drill Bit (HSS/Steel) | HSS/Carbon Steel | 30 (seco) | 0.15 (perforación) | 10 (single pass) | 8 minutos |
La perspectiva de la tecnología de Yigu
En la tecnología yigu, Sabemos dominar el elements of CNC machining is key to solving users’ efficiency and quality pain points. Many clients struggle with unbalanced parameters—wasting time on slow speeds or replacing tools too often. Our solutions include a “Parameter Matching Tool” that recommends cutting speed, alimentar, and depth based on tool/workpiece pairs. We also offer carbide tool bundles optimized for common materials (P.EJ., aluminum-specific carbide tools) to simplify setup. As CNC tech evolves, we’ll add AI-powered sensors to auto-adjust elements in real time, helping users achieve precision without manual trial-and-error.
Preguntas frecuentes
1. Can I use the same cutting speed for all machining operations (molienda, perforación, torneado)?
No—operations have different requirements. Drilling needs slower speeds than milling (drills have smaller cutting edges that overheat faster). Por ejemplo: Carbide drill on aluminum = 250 m/mi (VS. 400 m/min for milling with the same tool).
2. What happens if I set the tool feed too low?
A too-low feed rate wastes time (P.EJ., a 0.05 mm/rev feed on rough machining doubles the time) and can cause “rubbing” (the tool slides over the workpiece instead of cutting), which wears out the tool faster. Aim for the largest feed rate that keeps surface quality or efficiency on track.
3. Do I need to adjust depth of cut for different tool types?
Sí! Fábricas finales (used for milling) can handle larger depths than drills (used for holes). A 10mm end mill on aluminum can take an 8mm depth, but a 10mm drill should only take 2–3mm per pass (drills are less rigid and prone to breaking with large depths).